Abstract: A method for converting a dielectric material including a type IV transition metal into a crystalline material that includes forming a predominantly non-crystalline dielectric material including the type IV transition metal on a supporting substrate as a component of an electrical device having a scale of microscale or less; and converting the predominantly non-crystalline dielectric material including the type IV transition metal to a crystalline crystal structure by exposure to energy for durations of less than 100 milliseconds and, in some instances, less than 10 microseconds. The resultant material is fully or partially crystallized and contains a metastable ferroelectric phase such as the polar orthorhombic phase of space group Pca21 or Pmn21. During the conversion to the crystalline crystal structure, adjacently positioned components of the electrical devices are not damaged.

Abstract: Self-aligned gate/junction for VTFET devices are provided. In one aspect, a method of forming a VTFET device includes: forming a stack on a wafer including a first c-SiGe layer, a c-Si layer, and a second c-SiGe layer, wherein the first c-SiGe layer serves as a bottom source/drain; forming fin hardmasks on the stack; partially recessing the second c-SiGe layer to form a fin(s) in the second c-SiGe layer, wherein the second c-SiGe layer that is partially recessed/fin(s) serve as a top source/drain; amorphizing the c-Si layer to form a-Si regions in between c-Si regions that serve as vertical channels; selectively removing the a-Si regions to form gate trenches; forming bottom/top spacers in the gate trenches; and forming gates in the gate trenches that are offset from the bottom/top source/drain by the bottom/top spacers. A VTFET device is also provided. The VTFET device is suitable for 3D monolithic integrated circuits.

Abstract: A method of forming a semiconductor structure includes forming one or more vertical fins each including a first semiconductor layer providing a vertical transport channel for a lower vertical transport field-effect transistor (VTFET) of a stacked VTFET structure, an isolation layer over the first semiconductor layer, and a second semiconductor layer over the isolation layer providing a vertical transport channel for an upper VTFET of the stacked VTFET structure. The method also includes forming a first gate stack including a first gate dielectric layer and a first gate conductor layer surrounding a portion of the first semiconductor layer of the vertical fins. The method further includes forming a second gate stack including a second gate dielectric layer and a second gate conductor layer surrounding a portion of the second semiconductor layer of the vertical fins. The first gate conductor layer and the second gate conductor layer are the same material.

Abstract: A semiconductor material layer is deposited on a p-type source/drain region of a p-type transistor device and an n-type source/drain region of an n-type transistor device. The p-type device transistor device and the n-type transistor device are formed on a substrate of a semiconductor device. The semiconductor device includes a trench formed through an inter-level dielectric layer. The inter-level dielectric layer is formed over the n-type transistor device and the p-type transistor device. The trench exposes the p-type source/drain region of the p-type transistor device and the n-type source/drain region of the n-type transistor device. An element is implanted in the semiconductor material layer to form an amorphous layer on p-type source drain region and the n-type source/drain region. The amorphous layer is annealed to form a first metastable alloy layer upon the p-type source/drain region and a second metastable alloy layer upon the n-type source/drain region.

Abstract: Techniques for providing a high temperature soft mask for semiconductor devices are described. In an embodiment, spin coating semiconductor device components with organic planarization material having a defined aromatic content aromatic content to provide an organic planarization layer. The method can further comprise ultra-fast annealing the organic planarization layer and forming an implanted or doped region in the semiconductor device. Three-dimensional FinFET components of a device can be spin coated with organic planarization material having high aromatic content, with the device cured at a first temperature. The organic planarization layer can be ultra-fast annealed at a second temperature that is greater than the first temperature. Aspects can include patterning the device, and forming an implanted or doped region in a semiconductor device.

Abstract: A method of forming an electrical device that includes forming an amorphous semiconductor material on a metal surface of a memory device, in which the memory device is vertically stacked atop a first transistor. The amorphous semiconductor material is annealed with a laser anneal having a nanosecond duration to convert the amorphous semiconductor material into a crystalline semiconductor material. A second transistor is formed from the semiconductor material. The second transistor vertically stacked on the memory device.

Abstract: A method of forming a semiconductor structure includes forming a stacked vertical transport field-effect transistor (VTFET) structure and a sacrificial layer in contact with a source/drain region of the stacked vertical transport field-effect transistor structure. A masking layer is formed over the sacrificial layer. The masking layer defines a pattern to be patterned into the sacrificial layer. The sacrificial layer is patterned based on the masking layer to form a patterned sacrificial layer and the masking layer is removed. A portion of the stacked VTFET structure is etched down to a surface of the patterned sacrificial layer and the patterned sacrificial layer is removed to form a channel exposing the source/drain region. A contact material is formed in the etched portion of the stacked vertical transport field-effect transistor structure and in the channel. The contact material is formed in contact with the exposed source/drain region.

Abstract: A method of forming a semiconductor device that includes providing a vertically orientated channel region; and converting a portion of an exposed source/drain contact surface of the vertically orientated channel region into an amorphous crystalline structure. The amorphous crystalline structure is from the vertically orientated channel region. An in-situ doped extension region is epitaxially formed on an exposed surface of the vertically orientated channel region. A source/drain region is epitaxially formed on the in-situ doped extension region.

Abstract: A method of forming a semiconductor structure includes forming a stacked vertical transport field-effect transistor (VTFET) structure and a sacrificial layer in contact with a source/drain region of the stacked vertical transport field-effect transistor structure. A masking layer is formed over the sacrificial layer. The masking layer defines a pattern to be patterned into the sacrificial layer. The sacrificial layer is patterned based on the masking layer to form a patterned sacrificial layer and the masking layer is removed. A portion of the stacked VTFET structure is etched down to a surface of the patterned sacrificial layer and the patterned sacrificial layer is removed to form a channel exposing the source/drain region. A contact material is formed in the etched portion of the stacked vertical transport field-effect transistor structure and in the channel. The contact material is formed in contact with the exposed source/drain region.

Abstract: A method of forming a semiconductor device that includes forming a vertically orientated channel in a semiconductor fin structure that is present on a supporting substrate; and depositing a doped amorphous semiconductor material on an upper surface of the semiconductor fin structure that is opposite a base surface of the semiconductor fin structure that is in contact with the supporting substrate. The method further includes recrystallizing the doped amorphous semiconductor material with an anneal duration for substantially a millisecond duration or less to provide a doped polycrystalline source and/or drain region at the upper surface of the semiconductor fin structure.

Abstract: Compressive and tensile stress is induced, respectively, on semiconductor fins in the pFET and nFET regions of a monolithic semiconductor structure including FinFETs. A tensile stressor is formed from dielectric material and a second, compressive stressor is formed from metal. The stressors may be formed in fin cut regions of the monolithic semiconductor structure and are configured to provide stress in the direction of FinFET current flow. The dielectric material may be deposited on the monolithic semiconductor structure and later removed from the fin cut regions of the pFET region. Metal exhibiting compressive residual stress is then deposited in the fin cut regions from which the dielectric material was removed. Gate cut regions may also be filled with the dielectric stressor material to impart substantially uniaxial tensile stress perpendicular to the semiconductor fins and perpendicular to electrical current flow.

Abstract: A method is presented for amplifying extreme ultraviolet (EUV) lithography pattern transfer into a hardmask and preventing hard mask micro bridging effects due to resist residue in a semiconductor structure. The method includes forming a top hardmask over an organic planarization layer (OPL), depositing a photoresist over the top hardmask, patterning the photoresist using EUV lithography, performing ion implantation to create doped regions within the exposed top hardmask and regions of hardmask underneath resist residue, stripping the photoresist, and selectively etching the top hardmask by either employing positive tone or negative tone etch based on an implantation material.

Abstract: A semiconductor structure is provided that includes a bulk semiconductor substrate of a first semiconductor material. The structure further includes a plurality of fin pedestal structures of a second semiconductor material located on the bulk semiconductor substrate of the first semiconductor material, wherein the second semiconductor material is different from the first semiconductor material. In accordance with the present application, each fin pedestal structure includes a pair of spaced apart semiconductor fins of the second semiconductor material.

Abstract: A vertical transport field-effect transistor architecture is fabricated using a fin-last fabrication technique that enables pre-patterning of sacrificial gate layers and/or sacrificial source/drain layers with substantially flat topography prior to fin formation. Fins are epitaxially grown in trenches extending vertically through the device layers. Discrete regions of the sacrificial layers are later removed and replaced with appropriate source/drain and/or gate materials. Dielectric spacer elements are used to constrain feature dimensions of the replacement materials.

Abstract: A semiconductor material layer is deposited on a p-type source/drain region of a p-type transistor device and an n-type source/drain region of an n-type transistor device. The p-type device transistor device and the n-type transistor device are formed on a substrate of a semiconductor device. The semiconductor device includes a trench formed through an inter-level dielectric layer. The inter-level dielectric layer is formed over the n-type transistor device and the p-type transistor device. The trench exposes the p-type source/drain region of the p-type transistor device and the n-type source/drain region of the n-type transistor device. An element is implanted in the semiconductor material layer to form an amorphous layer on p-type source drain region and the n-type source/drain region. The amorphous layer is annealed to form a first metastable alloy layer upon the p-type source/drain region and a second metastable alloy layer upon the n-type source/drain region.

Abstract: A technique relates to fabricating a pFET device and nFET device. A contact trench is formed through an inter-level dielectric layer (ILD) and a spacer layer. The ILD is formed over the spacer layer. The contact trench exposes a p-type source/drain region of the pFET and exposes an n-type source/drain region of the NFET. A gate stack is included within the spacer layer. A p-type alloyed layer is formed on top of the p-type source/drain region in the pFET and on top of the n-type source/drain region of the nFET. The p-type alloyed layer on top of the n-type source/drain region of the nFET is converted into a metallic alloyed layer. A metallic liner layer is formed in the contact trench such that the metallic liner layer is on top of the p-type alloyed layer of the pFET and on top of the metallic alloyed layer of the nFET.

Abstract: Compressive and tensile stress is induced, respectively, on semiconductor fins in the pFET and nFET regions of a monolithic semiconductor structure including FinFETs. A tensile stressor is formed from dielectric material and a second, compressive stressor is formed from metal. The stressors may be formed in fin cut regions of the monolithic semiconductor structure and are configured to provide stress in the direction of FinFET current flow. The dielectric material may be deposited on the monolithic semiconductor structure and later removed from the fin cut regions of the pFET region. Metal exhibiting compressive residual stress is then deposited in the fin cut regions from which the dielectric material was removed. Gate cut regions may also be filled with the dielectric stressor material to impart substantially uniaxial tensile stress perpendicular to the semiconductor fins and perpendicular to electrical current flow.

Abstract: A method is presented for amplifying extreme ultraviolet (EUV) lithography pattern transfer into a hardmask and preventing hard mask micro bridging effects due to resist residue in a semiconductor structure. The method includes forming a top hardmask over an organic planarization layer (OPL), depositing a photoresist over the top hardmask, patterning the photoresist using EUV lithography, performing ion implantation to create doped regions within the exposed top hardmask and regions of hardmask underneath resist residue, stripping the photoresist, and selectively etching the top hardmask by either employing positive tone or negative tone etch based on an implantation material.

Abstract: A method of forming a semiconductor device that includes providing a vertically orientated channel region; and converting a portion of an exposed source/drain contact surface of the vertically orientated channel region into an amorphous crystalline structure. The amorphous crystalline structure is from the vertically orientated channel region. An in-situ doped extension region is epitaxially formed on an exposed surface of the vertically orientated channel region. A source/drain region is epitaxially formed on the in-situ doped extension region.

Abstract: A method of forming a semiconductor device that includes forming a vertically orientated channel in a semiconductor fin structure that is present on a supporting substrate; and depositing a doped amorphous semiconductor material on an upper surface of the semiconductor fin structure that is opposite a base surface of the semiconductor fin structure that is in contact with the supporting substrate. The method further includes recrystallizing the doped amorphous semiconductor material with an anneal duration for substantially a millisecond duration or less to provide a doped polycrystalline source and/or drain region at the upper surface of the semiconductor fin structure.